In some aspects, systems and methods provide for forming groupings of a plurality of independently-specified computation workloads, such as graphics processing workloads, and in a specific example, ray tracing workloads. The workloads include a scheduling key, which is one basis on which the groupings can be formed. Workloads grouped together can all execute from the same source of instructions, on one or more different private data elements. Such workloads can recursively instantiate other workloads that reference the same private data elements. In some examples, the scheduling key can be used to identify a data element to be used by all the workloads of a grouping. memory conflicts to private data elements are handled through scheduling of non-conflicted workloads or specific instructions and/or deferring conflicted workloads instead of locking memory locations.
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10. A method of processing data using a plurality of computation elements, each of the computation elements comprising a local memory and a plurality of single instruction multiple data (SIMD) Arithmetic Logic Units (ALUs), the method comprising:
instantiating one or more fibres;
assigning a storage allocation to a fibre of the one or more fibres;
storing the one or more fibres which are ready for execution; and
scheduling work to be executed on the computation elements from among the stored one or more fibres and other workloads;
wherein execution of computer executable instructions associated with a parent fibre of the one or more fibres by a computation element instantiates one or more descendent fibres, the parent fibre having a storage allocation assigned thereto, and the instantiated one or more descendent fibres inheriting access to said storage allocation of the parent fibre, and wherein said scheduling prevents two or more descendent fibres which are descended from the same parent fibre being executed in parallel on the computation elements.
1. A processing system comprising:
a plurality of computation elements, each of the computation elements comprising a local memory and a plurality of single instruction multiple data (SIMD) Arithmetic Logic Units (ALUs), wherein the computation elements are operable to execute computer executable instructions to instantiate one or more fibres;
an allocator operable to assign a storage allocation associated with a fibre of the one or more fibres;
a ready unit configured to hold the one or more fibres for later execution; and
a scheduler operable to schedule work for the computation elements from among the one or more fibres held in the ready unit and other workloads,
wherein the processing system is configured such that execution of computer executable instructions associated with a parent fibre of the one or more fibres by a computation element instantiates one or more descendent fibres, the parent fibre having a storage allocation assigned thereto, and the instantiated one or more descendent fibres inheriting access to said storage allocation of the parent fibre, and wherein the scheduler is configured to prevent two or more descendent fibres which are descended from the same parent fibre being scheduled to be executed in parallel.
17. Graphics processing apparatus comprising:
a plurality of computation elements, each of the computation elements comprising a local memory, and a plurality of single instruction multiple data (SIMD) Arithmetic Logic Units (ALUs), wherein the computation elements are operable to execute computer executable instructions to instantiate one or more fibres;
allocation logic configured to assign a region of a local memory of one of the computation elements to a fibre of the one or more fibres as a storage allocation;
a ready store configured to store the one or more fibres for subsequent execution, wherein the ready store is distinct from the computation elements; and
scheduling logic configured to schedule, based on the storage allocations assigned by the allocation logic, work to be executed on the computation elements from among the one or more fibres stored in the ready store and other workloads, wherein the scheduling logic is distinct from the computation elements and distinct from the ready store;
wherein the graphics processing apparatus is configured such that execution of computer executable instructions associated with a parent fibre by a computation element instantiates one or more descendent fibres, the parent fibre having a storage allocation assigned thereto, and the instantiated one or more descendent fibres automatically inheriting access to said storage allocation of the parent fibre, and wherein the scheduling logic is configured to prevent two or more descendent fibres which are descended from the same parent fibre being scheduled to execute in parallel.
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This application is a continuation of U.S. patent application Ser. No. 13/567,091, filed on Aug. 6, 2012, now U.S. Pat. No. 8,692,834, issued on Apr. 8, 2014, which is a continuation of PCT/2012/42591, filed on Jun. 15, 2012, entitled “Graphics Processor with Non-Blocking Concurrent Architecture”, which claims priority from U.S. Provisional Patent App. No. 61/497,915, filed on Jun. 16, 2011, all such applications are hereby incorporated by reference in their entireties, for all purposes.
The following relates generally to utilization of parallel processing resources, and in one more particular aspect, to programming interfaces and architectures that can be used in different classes of parallel computing problems, and in particular to graphics processing, including ray tracing.
Computer architectures seek to increase parallelism at a hardware level and at a software/operating system level. A variety of techniques have been proposed to address parallelism for hardware and software. One general concept is to use multi-threading as a mechanism to increase parallelism.
Regarding software-based multithreading, an operating system can concurrently execute multiple processes (typically, multiple independent programs) on a single hardware execution resource by interleaving in time the execution of the processes. Such interleaving can be accomplished by an OS kernel, which determines what process has priority, and also can access the resources it needs to proceed with execution.
When a process has two or more semi-independent subtasks, multiple threading can increase throughput, give better response time, speed operations, improve program structure, use fewer system resources, and make more efficient use of multiprocessors. With multi-threading, a process has multiple threads of control. The concept of multithreaded computing is increasingly common, as faster clocks for processors becomes prohibitively power consumptive, and transistor budgets are used on wider architectures. As such, the term “thread” has come into increasing usage, but is not always used to refer to the same concept, but rather a context of usage can inform the meaning of the term.
A process can be viewed as an individual program or application that can be executed. As such, a process has a sequence of instructions to be executed. A thread also has a sequence of instructions for execution, but typically is more granular. For example, a function can represent a thread's sequence of instructions. If instantiated by a process, a thread shares that process' address space, yet can own unique resources within the process. Instructions from each thread can be individually scheduled, which allows threads of a process to be executed concurrently, as resource availability dictates.
Threads can be managed by a creating process and be invisible to a kernel of an operating system (also referred to as user-level or application-level threads). User threads are handled in user space, and controlled using a thread API provided in a library. Such control includes operations such as creation, termination, synchronization, scheduling. Creation, termination, and synchronization operations can be performed using user-space threads. Because user-space threads are not directly visible to the kernel (which is aware only of the overriding process containing the user-space threads), if a user-space thread blocks, its entire process blocks. When this happens, the benefit of threads parallelism is lost or reduced. Additional layers of complexity can be introduced to reduce blocking, but at a performance cost.
Kernel threads are handled in kernel space and created by the thread functions in the threads library. Kernel threads are kernel schedulable entities visible to the operating system. Kernel threads exist within the context of a process and provide the operating system the means to address and execute smaller segments of the process. Kernel threads also enable programs to take advantage of capabilities provided by the hardware for concurrent and parallel processing. With kernel threads, each user thread can have a corresponding kernel thread. Each thread is independently schedulable by the kernel, so if an instruction being executed from one thread blocks, instructions from other threads may be able to run. Creation, termination, and synchronization can be slower with kernel threads than user threads, since the kernel must be involved in thread management. Overhead may be greater, but more concurrency is possible using kernel threads, even with a uniprocessor system. As a result, total application performance with kernel-space threads can surpass user-space thread performance. However, developers must be more careful when creating large amounts of threads, as each thread adds more weight to the process and burdens the kernel.
Kernel threads can change the role of processes, in that a process is more of a logical container used to group related threads of an application in such an environment. Each process contains at least one thread. This single (initial) thread is created automatically by the system when the process starts up. An application must explicitly create the additional threads. An application with only one thread is a “single-threaded.” An application with more than one thread is a “multi-threaded.” An example treatment of a thread with respect to other threads is provided below.
A process's “state” information includes a program counter indexing a sequence of instructions to execute, and register state. The register context and program counter contain values that indicate the current state of program execution. The sequence of instructions to execute is the actual program code. For example, when a process context switch takes place, the newly scheduled process's register information tells the processor where the process left off in its execution. More specifically, a thread's program counter would contain the current instruction to be executed upon start up.
Like the context of a process, the context of a thread consists of instructions, attributes, user structure with register context, private storage, thread structure, and thread stack. Like a process, a thread has a kind of life cycle based on the execution of a set of control instructions. Through the course of time, threads, like processes, are created, run, sleep, and are terminated. New processes (and in a multi-threaded OS, at least one thread for the process) typically are created using a fork( ) call, which produces a process and thread ID. The process and its thread are linked to the active list. The new thread is flagged runnable, and thereafter it is placed in a run queue. The kernel schedules the thread to run, changing the thread state to an active running state. While in this state, the thread is given the resources it requests. This continues until a clock interrupt occurs, or the thread relinquishes its time to wait for a requested resource, or the thread is preempted by another (higher priority) thread. If this occurs, the thread's context is switched out.
A thread is switched out if it must wait for a requested resource (otherwise, the processor would block). This causes the thread to go into a sleep state. The thread sleeps until its requested resource returns and makes it eligible to run again. During the thread's sleep state, the kernel charges the currently running thread with CPU usage. After a period of time, the kernel can cause a context switch to another thread. The next thread to run will be the thread with the highest priority of the threads that are ready to run. For the remaining threads in that ready state, their priority can be adjusted upwards. Once a thread acquires the requested resource, it calls the wakeup routine and again changes state from sleep to run, making the thread eligible to run again. On the next context switch the thread is permitted to run, provided it is the next eligible candidate. When allowed to run, the thread state changes again to active running. Once the thread completes, it exits, releases all resources and can transfer to a zombie state. Once all resources are released, the thread and the process entries are released and the linked lists of active processes/threads can be updated.
Regarding more hardware-oriented parallelism, the capability of implementing parallel computing hardware is available in almost all computing devices, ranging from powerful mobile or desktop CPUs that may have 4, 8, 16, 32 or several dozen processing elements that are relatively complex to Graphics Processing Units (GPU) with many (e.g., hundreds) of relatively simple processors.
While GPU's where originally designed and still are primarily used to accelerate raster graphics, GPUs have gradually become more programmable. Such increased programmability has allowed for some multi-threaded computing problems to be expressed and executed on GPUs. Although GPU architectures have extremely high theoretical peak Floating Point Operations per Second (FLOPS), only rasterised graphics and certain well behaved, highly streamable compute problems can come close to realizing an actual throughput near to the theoretical throughput.
Increasing parallelism of computation typically involves a tradeoff between algorithmic complexity and overhead incurred in managing sharing of computation resources. Another important consideration is that algorithms execute correctly, such that data values are not corrupted. Parallel execution of threads, which may use shared data can cause data corruption by improper timing of reads and writes to shared data values. Negotiating access or serializing access to such shared data values incurs overhead.
Another concern largely is ensuring correctness of data during increasingly parallel execution. Principally, parallelism (and avoidance of data corruption) among different threads is handled through locks on variables that are at risk for being written (or read) out of correct order by conflicting processes in a system. The concept essentially is that when a given process wants to write to such a variable (e.g., a global variable), the process attempts to lock the variable. If no other process has a lock on the variable, then the lock can be granted to the requesting process. The process performs its write, and then releases the lock. As can be discerned, the usage of locks depends on a mechanism to detect or identify which variables should be protected by locks, and an arbiter to check lock status, grant lock status, and revoke lock status. Often, which variables need to be protected depends also on whether a given software procedure is intended to be available for usage on multithreaded platforms, in which a number of such instances of such procedure may be executing in concurrently executing processes.
Programmers can specify portions of code in a process to be protected by a lock. At compile time, a compiler can process such code, and in some cases also could detect variables that may be at risk, but which were not protected, and can insert such locks into the compiled object code.
One implementation of a lock is Mutual Exclusion (mutex), which controls how different portions of computer code can access a shared resource, such as a global variable. For example, a portion of code that needs to read a given variable should not be allowed to execute during an update of that variable by another process. The term mutex also is used in the sense of a program element that operates to negotiate a mutual exclusion of different program elements for conflicting variables. In a multi-threaded execution environment, a number of threads can be executing, and ultimately may need to access a given data object protected by a mutex. If the mutex currently is active, then typically the operating system will cause the threads that are waiting for that mutex to go to sleep (i.e., cease execution). Thus, as more and more threads reach the mutex, they each are made to go to sleep to await a time when the operating system indicates that they can continue execution. The operating system can wake these threads by a relative order in which they arrived at the mutex; the order in which they are awakened may simply be indeterminate.
Other approaches to allocation of shared resources includes semaphores, which allocate a set of undifferentiated resource elements among processes that desire to use the elements. A semaphone essentially counts how many elements of the resource are available for use from the set, adjusting the count as resources are reserved and released. When no elements of a given resource are available, then a process requesting use of the resource waits until an element of the resource has been released. Typically, semaphores are implemented in operating systems for resource allocation.
Variations on basic locking concepts exist, such as spinlocking, which allows threads to continue to actively ask when a given lock is free, such that their responsiveness is increased by not having to be awakened, which incurs overhead (context swapping). However, spinlocking does use processor cycles, and consequently inherently reduces efficiency. Other variations include recursive locking, implementing time limits on locks, such that a process will not wait indefinitely to acquire the lock for a particular object, but instead continue execution, if possible, if its lock request is not fulfilled in a given time period. Such an approach is useful in embedded systems, where absolute timing execution for critical processes may be necessary.
A further example variation is recursive locking, which is a strategy proposed for computing architectures that have Non-Uniform Access (NUMA) to a shared memory. Typically, groups of general purpose processors, each with an onchip cache, and operating in a system with a shared main memory will have NUMA properties (practically, a large majority of low-cost computation platforms). Recursive locking is based on the realization that a process resident on a processor that has a locked memory location (standard test and set locking) is more likely to be granted access to that locked memory location than a process executing on a different chip, due to differences in communication delay incurred by interconnect between the processors. Recursive locking seeks to enforce a predictable and controllable preference for granting a lock to a process that may have more data locality by granting locks to processes executing on the node that already has the lock by adding a condition to the lock granting process that tests an identifier for which node is hosting the thread requesting the lock.
Aspects of an example system for performing concurrent graphics computation, include a cluster of computation elements, where each computation element comprises a local memory, and a plurality of Single Instruction Multiple Data (SIMD) Arithmetic Logic Units (ALUs). The system also has a scheduler for the cluster of computation elements. The scheduler is operable to receive inputs defining instances of a first type of computation to be performed on the cluster, where each of the instances is associated with a respective scheduling key. The scheduler is operable to sort the instances according to their scheduling keys into packets, and emit a packet comprising a plurality of instances of computation. The system has a distributor that is operable to receive the packet, and distribute the instances among the computation elements of the cluster. Each of the computation elements is operable to combine instances with different scheduling keys for concurrent execution, for which the same computation is to be performed and to concurrently execute the computation for the combined discrete portions of computation.
Exemplary further aspects can include that instances can be synchronized for memory accesses to memory locations that are open to reading and writing with other instances by identifying conflicting memory ranges among different instances, before instructions accessing those conflicting memory ranges have been dispatched for execution. The scheduler can perform such identifying of conflicting memory ranges using instance-specific memory addresses for a variable declaration. The system can disperse instance-specific memory ranges among the plurality of computation elements during a setup phase. Each computation element can be operable to schedule groupings of instances of the second type of computation according to criteria comprising (1) execution from a common source of instructions, and (2) enforcing a rule that no grouping of instances to be executed in parallel may include multiple instances that write the same memory location.
In a further exemplary aspect, a method to be performed in scheduling graphics computation on a computer system, provides for distributing workloads of a first type among a plurality of computation clusters. Each cluster is operable to schedule execution of instructions from first type workloads assigned to that cluster independently from other clusters of the plurality. Groupings of workloads of a second type are formed for execution in the plurality of computation clusters. The groupings are determined based on respective scheduling keys associated with workloads of the second type. Each scheduling key defines one or more of a data element to be used during execution of each grouping of workloads and a set of instructions to be executed for each workload of the second type. A grouping of workloads is selected and workloads of the grouping are distributed, among the plurality of computation clusters.
A further exemplary aspect includes a computation component for use in a computation system, comprising: a memory comprising a transitory portion and a persistent storage portion. The component further comprises a plurality of Arithmetic Logic Units (ALUs), each having read and write access to the memory and an input queue for receiving discrete definitions of computation to be performed on the plurality of ALUs. The definitions comprise a program reference, and a scheduling key. A local scheduler is operable to schedule the plurality of ALUs. The local scheduler is operable to prioritize scheduling of computation by identifying groupings of definitions of computation that have the same program reference and the same scheduling key. The scheduling key is used for identifying a location in the high turnover portion of the memory storing data to be used by the ALUs when executing the referenced program.
In a further aspect, a tangible computer readable medium having computer executable instructions stored comprises instructions for a thread of computation to be executed on a computation unit. The instructions for the thread comprise instructions to call a computation routine. The call of the computation routine comprises a definition of a scheduling key, a limited memory reference identifying a memory location for reading and writing, and a memory location to be read for that computation routine, and instructions that are to be executed after calling the computation routine, without waiting for return of information produced by the called computation routine during its execution. The computation routine further can be recursively instantiated, and each recursively instantiated instance automatically inherits the limited memory reference, and the read memory location is different. The read memory location can be updated based on a regular access pattern of a type of data being accessed.
One reason that parallelism does not scale in accordance with computation resource availability is that memory bandwidth is not scaling in proportion to the available computation capability. Therefore, computational problems that do not enjoy inherent data locality can cause the computation elements to wait on data being accessed from memory. Memory access remains a problem even as peak theoretically available memory bandwidth has gone up, because such peak bandwidths assume burst transfer rates that often are unrealistic for these kinds of computation problems. Further, scalability of memory interface performance is hindered by other factors, such as pin count of the memory interface, and the fact that memory access latency does not readily scale with process technology changes. For example, DDR3 Column Address Strobe (CAS) latency can be around 9 ns, while typical DDR2 CAS latency is around 10 ns. Also, memory latency between processing nodes also may be a factor in different computational paradigms, such as NUMA architectures.
Further, the SIMD nature of the compute clusters means that simultaneously executing threads must follow identical program execution paths in order to realize peak computation throughput. For example, if half of the threads in such a SIMD cluster take a branch one way and the remainder the other branch, the hardware must serialize these two paths (i.e., one half stalls while the other half executes so that ultimately, the SIMD cluster can once again execute on vectorized data). In such a situation, the computation unit executes at only 50% throughput. In situations where a code base being executed contains many branches, a worst case performance from SIMD loss alone can be 1/SIMD_width, which is about 3% efficiency on a 32 wide SIMD architecture. There are a large number of computing problems, including ray tracing, spatial search, sorting and database traversal which, while theoretically parallizable, have not mapped efficiently to such wide SIMD architectures.
Some applications of the technology described below relates to graphics processors, such as processors that can perform rasterization and/or ray tracing. With particular regard to ray tracing, ray tracing can be used to produce realistic images rendered from 3-D scenes, in the context of video games, motion pictures, animated advertisement, industrial models, architectural simulation, and so on. One construct employed in the field of rendering is to provide a physical scene model, and associate surface information with different parts of the scene model. For example, a scene model can contain objects including a person, an automobile, and a building. The physical model of the scene would describe the surfaces of these objects, for example, as a wire frame model, which can include a large number of primitive shapes interconnected with each other to describe boundaries of the surfaces. This physical model generally lacks information about the visual appearance of the objects' surfaces. Then, information and programming is associated with particular surfaces, and/or portions of particular surfaces that describe their appearance. Such information can include textures for the surfaces, while programming associated with the surfaces often is intended to model what effect the surface has on light hitting the surface. For example, programming allows modeling of glass, a shiny surface, a bumpy surface and so on. Such programming and information thus is bound or otherwise associated with portions of the physical model descriptive of those surfaces. For example, programming can be associated with or bound to a particular primitive. Such programming and other description, or portions thereof, for a particular primitive or scene object can be referred to generally as a “shader” for that primitive or object.
The above description shows that the term “thread” can connote different meanings in different circumstances (but is not an exhaustive explanation of potential usages of the term). Therefore, in the description that follows, terminology will be used in an attempt to reduce reliance on terminology associated with multi-threading, e.g., by introducing the term “fibre” as a moniker that is intended to refer collectively and individually to a plurality of concepts, not all of which may need to be practiced in every implementation according to this disclosure. Nevertheless, multi-threaded operating systems, and machines that support concurrent and parallel processing of multi-threaded applications may be adapted to implement aspects of these disclosures, as will become more apparent from the description that follows.
In one aspect, a process in a multiprocessing environment, or a thread in a multi-threaded environment (or both, in a multiprocessing, multi-threaded environment) can use an API to create one or more units of work to be performed, each called a “fibre” herein, for sake of convenience.
In one aspect, a fibre is an instance of code, such as a routine, (e.g., a C function declaration) that can be forked repeatedly by a parent thread or recursively entered from another instance of the same fibre routine. An instance of a fibre routine (instances of fibre routines are, for convenience, simply called “fibres”) includes an identifier for an element of data used as a scheduling key, and identification of a particular element (a declaration of) of fibre storage.
Fibres sharing a scheduling key can be grouped for concurrent execution (as described below, such grouping does not impose a requirement that such execution occur strictly in parallel). All fibres referencing the same element of fibre storage can be channeled for execution to a computation element having that element of fibre storage locally cached. In one exemplary implementation, a given element of fibre storage, for a given fibre, or set of fibres, has at least the characteristic that this element of fibre storage is readable and writable only by that fibre, or set of fibres; this limitation can be time-variant, or absolute. This limitation can be enforced by appropriate programming practices, by a compiler, by hardware, and by some combination thereof.
In one aspect, a fibre can be defined by a standard C function declaration and contains all the code required to execute the fibre to completion (standard inline expansions of functions can be provided). An operative difference being that a fibre is not to wait for a return value from another function called within the fibre. In the exemplary aspect, the fibre routine function declaration contains at least one argument for which a value is stored in fibre storage associated with the thread that forks fibres using that fibre routine declaration.
In one exemplary aspect, all fibres that reference a given element of fibre storage (e.g, instantiated by a parent thread (or fibre) have their execution controlled or distributed, so that they execute serially within a given processor (a processor can itself by a grouping of processing elements, and in one example, can include a plurality of SIMD processor elements), and concurrently or generally in parallel with other fibre routines that have the same (or matching) fibre key(s). In one example, a grouping of processor elements considered to be a processor, in this context, is determined according to which processing elements can write to a particular fibre storage location. In one example, all processor elements that can write to a particular fibre storage location are considered as a group to be a processor, for the purposes of enforcing serial execution of fibres that reference that particular fibre storage location. Such writing can be considered with respect to a subset of memories in a system, such as local memories, whereas accesses may not be so treated.
In one exemplary aspect, only fibres that ultimately trace to a common parent access a fibre storage element allocated for these fibres. Thus, a fibre that traces to a different parent for that set do not access such fibre storage location. Further, in exemplary aspects, no two or more fibres from the same parent are scheduled to be executed in parallel, so that no mutex or lock management is required to fibre storage locations.
However, in such exemplary aspect, a fibre otherwise can have full access to all the features that a standard thread would have, including full global memory access, local memory, barriers, texture samplers, private variables and all arithmetical and logical operations. The fibre routine may also contain arguments that are directly taken from the kernel arguments of its parent thread, which allows the fibre to have access to global memory pointers and other shared variables. These memory locations can be accessed using standard memory protection techniques.
Each thread in the system can define a plurality of fibres, each with a respective scheduling key. Further, a plurality of fibre routines can be defined, such that a given thread can define a number of fibres, which are instances of different fibre routines. As explained above, in an exemplary aspect, fibres of the same fibre routine (sharing a code base), and from the same parent (e.g., a parent thread or fibre), do not overlap in execution in implementations that avoid mutexes or locks for accessing at least one variable or data source that is available only to these fibres.
In some implementations, an API can be provided for instantiation/invocation of fibre routines (each fibre being an invocation of a fibre routine, as explained above) by a parent thread (or another fibre) through a semantic (an example of which is provided below). In some aspects, and unlike a function call in a typical multi-threaded environment, a kernel (or other system scheduler resource) does not necessarily immediately attempt to execute, or make preparations to execute, the fibre such invoked (as it would a thread, in a typical multi-threaded environment). Examples of such preparations were introduced above.
Instead, in one exemplary aspect, its activation (allocating actual processing resources for execution) is deferred until an unknown future time. Further, after a parent thread instantiates a fibre (e.g., by using a fibre definition API semantic), the parent thread can continue execution if otherwise permitted (e.g., continue to be an active thread, incrementing its program counter and using hardware resources). An API also can provide a semantic for instantiating a number of fibres (e.g., of the same fibre routine or of different fibre routines) at the same time. In one example, each of the fibres can have a common fibre key, and in another example, the fibres can have the same fibre key, but operate on one or more different values.
Because, in this exemplary aspect, a parent thread does not block or wait for a return value from this fibre, a fibre does not return any return value to a parent thread, as would a standard C function. By contrast, upon completion, a fibre routine can simply cease to exist (e.g., go into a zombie state, awaiting deallocation of memory resources), and does not return to the caller (parent) thread. Thus, for a fibre, in this aspect, to have effect or produce useful output, the fibre is to write results into fibre storage. Note that although the fibre has the capability to write results to a memory resource shared outside of the fibre (e.g., global or local memory), using a mutex or locking management, such an operation would be much slower than a write to fibre storage.
In an exemplary aspect, because fibres do not return a value, data that persists between fibres (e.g., fibres instantiated from a common thread) is confined by data resident or declared as resident in fibre storage. In practice, it is expected that the exemplary aspects disclosed herein would be practiced by allocating a fast available memory resource to fibre storage, and as such, would typically be expected to be a more limited resource. For example, as between a main memory and a cache memory, a comparatively larger portion of the cache would be dedicated to fibre storage than to other data that may be used by fibres.
Another aspect of some generality is that fibres that reference the same element of fibre storage are reference counted (e.g., a counter is incremented when a fibre referencing that element of fibre storage is emitted, and decremented when such a fibre completes). A reference count hitting zero thus indicates that there are no more fibres outstanding which reference a given fibre storage location (or locations in a case where a given set of fibre references a number of locations). Thus, such a reference count reaching zero can be a trigger to a parent thread that data in the fibre storage is available for usage and/or fetching. A flag set in response to the zero value, such as a flag provided by a built in function can be monitored by the parent thread, by way of further example.
The following is an example construct of coding semantics that can be used in an implementation according to these disclosures. This example is by way of explanation, and not limitation as to how a particular implementation may be structured, or the contents of such an implementation.
_fibre: This qualifier is used to declare a function as being a fibre routine. A fibre routine place this qualifier at the beginning of the function declaration.
_fibrestorage: This qualifier declares a variable as being present in fibre storage. Inside a parent thread, variables that are to be shared between child fibres are declared with this qualifier. Fibre routines do not declare fibre storage. Fibre routines contain at least on argument that has this qualifier.
_fibrekey: A fibre key is used to indicate one or more criteria used in scheduling the execution of the fibre. Examples of fibre keys include an offset in global memory, and a branch condition. A platform can schedule a fibre to run in parallel with other fibres based on fibre key matching. In one implementation, a fibre routine function declaration contains exactly one argument of this type.
+Fibreroutine(a,b): A fibre routine is invoked by making a standard function call but placing a +symbol ahead of the function name. Such invocation does not cause a jump execution to the fibre routine immediately, but rather defers its invocation to a future time. Execution of the calling routine can continue as normal, and the fibre routine does not return a value, as does a normal function call.
bool is_initial_thread_Iaunch( ): This is a built-in function which only returns true when called by the parent thread on its initial launch. This function is provided for convenience to differentiate between the parent thread routine being called by a typical thread launch, and notification that all child fibres from a parent thread are finished (can be determined by a reference count hitting zero).
The pseudocode in the Appendix exemplifies an approach to fibre computing, in which threads can instantiate fibres that behave according to this disclosure, and in which fibres can recursively instantiate other fibres that reference the same fibre data storage, but which have varying scheduling keys.
In view of the above introductory explanation and by way of further explanation, a variety of architectural examples and operational situations are explained below. Architectures in which fibre computing aspects can be practiced are diverse. One exemplary type of architecture is one where a plurality of computation clusters each comprise a plurality of Arithmetic Logic Units (ALUs), and a local controller that controls the ALUs. In a more particular instance of such architecture, all the ALUs of a cluster are run from a common program counter selected by the local controller. Each ALU, however, can have an independent port to a local memory. In some examples, the local memory can operate similar to a register set of a general purpose processor; each ALU can read and write to and from the local memory. In some implementations, the active program counter in each cluster can be changed on an instruction by instruction basis, without latency. In some architectures having such a plurality of clusters, full threads can be executed in each cluster, and state for such threads maintained in the local memories of the clusters. In some implementations, a local controller may treat fibres differently from threads, in terms of scheduling their execution in the ALUs controlled by that local controller. In some implementations, no fibre that references a common fibre memory storage location (i.e., the fibres share a common origin) would be scheduled for concurrent execution in the cluster in any implementation where memory arbitration is not implemented. One example architecture explicitly avoids arbitrating for local memory access by fibres, so that memory accesses can be accelerated.
Example workloads processed in computation architectures implementing disclosed aspects primarily relate to graphics rendering workloads, and more particularly, ray tracing is provided as a principal application example of fibre computing principals. However, a variety of computational problems can be addressed by application of disclosed aspects of fibre computing. In the context of implementing ray tracing functionality using aspects of fibre computing, a graphics chip may continue to implement rasterization based graphics processing with thread computing principals and using the same plurality of computation clusters. Vertex and pixel shading functions, which may apply to geometry and image processing for similarly can be implemented according to fibre computing or thread computing principles.
Fibre computing system architectures thus provide for acceptance of workloads specified from divergent sources, such as different threads or other fibres. Each workload can have a first and a second data element, where one of the data elements can be used as a scheduling key to control how that workloads is grouped with other workloads, and the other controls where, among a plurality of computation elements, that workload is executed.
Example system architectures in which disclosed aspects may be practiced are depicted in
A host interface 40 may includes a thread API 42 and may include a fibre API 41. Thread API 42 can be used by routines miming on a host processor (not depicted), in order to instantiate new threads to be executed on system 10. Thread API 42 can be provided, for example, as a firmware coded API available in a System on Chip (SoC) with one or more generally programmable processor cores, such as a computation core operating according to an architecture specification and with an instruction set architecture. In other examples, thread API 42 can be provided with a driver for an add-on card that off-loads graphics processing loads from the host processor.
In one example, and as described below, fibre API 41 can be used by threads running on the host processor, to instantiate fibres that are executed in systems according to example system 10. As will be described below, threads executing in such systems also can access an API provided according to these disclosures, such that threads executing on the system also can define fibres for execution. In some examples, a fibre API is not exposed at the host interface level, but rather is made available only to threads executing within the graphics processor system 10.
Example system 10 includes a number of masters, which function to setup computation to be performed in system 10. In some examples, computation performed in system 10 is considerably more regular and voluminous than typical application code intended for execution on a processor. Rather, example workloads can include workloads to shade large set of vertices or pixels. Vertex data master 10 and pixel data master 11 can be provided to setup the usage of the available computation elements (described below) to perform such computation). By further example, compute data master 2 and ray data master 13 can be provided to setup computation for a large scale numerical analysis programs, and for ray tracing workloads.
Coarse scheduler 44 receives inputs from data masters, such as data masters 10-13, described above. Coarse scheduler can operate to allocate independently operable computation elements to perform the computation loads that can come from the data masters. Coarse scheduler receives status information from resources available in system 10. Such resources include status of memories located within an array of clusters 65 (described below). Such memories may be private to particular computation units (e.g., cores 70-73) within the array of clusters 65, such as memories 76-79. These memories 76-79 can be implemented as caches that can be allocated among threads that are executing on the core coupled with each memory (e.g., memory 76 can be allocated among threads executing on core 71). The allocation of such memory can be handled by coarse scheduler 44. Each data master (vertex, pixel, computer, ray) can communicate memory allocation requirements to coarse scheduler 44. Aspects of operation of coarse scheduler 44 and communication between a data master, for the purposes of thread scheduling and resource allocation, is described in U.S. Patent Pub. No. 2007/0101013 to Howson, which is incorporated by reference in its entirety herein. Such operation is exemplary, rather than exhaustive; such operation also may be adapted in view of the present disclosures.
The exemplary system 10 also includes a packet unit 105 that includes constituent components of a ready stack 106, a collection definition memory 107, an empty stack 108, and a packer unit 109. The functionality, usage, and operation of packet unit 105 within example architecture 10 will be described below. Example system 10 also may comprise a variety of co-processors adapted to perform specific functions, and are depicted as co-processors 115-117. Other special purpose functionality can be provided, such as texture loader 118.
Exemplary system 10 also may comprise a cache hierarchy 15 that includes one or more levels of cache memory, and a system memory interface 16 that can interface with a main memory, which can be implemented as one or more of high speed graphics RAM, DRAM, and the like. Approaches to large scale memory capacity may be adapted as new technologies are developed, and usage of well-known acronyms, such as DRAM, is not intended to confine the applicability of disclosed aspects to a given process or memory technology.
In one example, a thread executing on a particular cluster can instantiate a fibre routine (thereby making a fibre). Coarse scheduler 222 can receive the information concerning the instance and allocate a particular cluster to execute the fibre. As introduced above, allocation of a fibre to execute on a cluster does not indicate that execution would commence immediately, but rather execution of such fibre depends on
An abstraction/distributor layer 225 separates a series of computation clusters (clusters 227 and 229 are depicted) from coarse scheduler 222 and from packet unit 205. Distributor layer 225 accepts groupings of fibres from packet unit 205 and causes the fibres to be distributed among the computation clusters, according to an exemplary approach described below. Layer 225 is an example means for distributing the groupings into regions of compute that will execute that computation.
Each cluster comprises a respective controller (controllers 230 and 232 depicted for cluster 227 and 229 respectively). Each cluster controller (e.g., 230 and 232) controls a plurality of arithmetic logic units (ALU) (e.g. cluster controller 230 controls a plurality of ALUs including ALU 235 and ALU 236). Each ALU of a cluster communicates with a thread local and fibre storage memory (e.g. thread local and fibre storage 240). In one implementation each ALU has a separate and dedicated access path to thread local and fibre storage, such that each ALU can read or write concurrently from and to the memory with the other ALUs of that cluster. Memory resources of a given cluster further comprise a broadcasted data memory (e.g. broadcasted data memory 260 of cluster 227). In an example implementation, broadcasted data memory 260 can be implemented in the same physical storage medium as thread local and fibre storage 240. An example implementation broadcasted data memory 260 can be highly interleaved cache that allows a particular location of memory map to a number of different locations in the broadcast data memory. In some implementations broadcasted data memory may comprise a ring buffer or FIFO memory implementation. These broadcasted data memories are fed by a direct memory access unit (DMA) 241. In one example implementation DMA 241 control storage of data in a plurality of broadcasted data memories in a number of clusters. A cluster is a means for performing concurrent computation on respective pluralities of data elements, using a respective single control flow.
Each cluster comprises an input buffer, e.g. cluster 227 comprises input buffer 267. Each input buffer for each cluster is written by distribution layer 225 and read by the respective controller of that cluster. For example distribution layer 225 writes to input buffer 267 which is read by cluster controller 230.
In view of the above introduction to the components of example system 202, aspects of the operation of this example system 202 are described below.
In the example depicted in
These concepts are depicted in
Regardless of the specific implementation sequence of instructions, e.g. instruction 462 and instruction 464 can be provided from instruction memory hierarchy 460 to a plurality of ALUs 471-473. Thus, in the implementation depicted in
The example of
The managed portion is allocated to specific store local data during computation, and does not have an expectation or goal of being coherent with another memory or memory hierarchy. The managed portion does not use tag memory or coherency indications, because the managed portion is setup with data in known locations, and the memory is not maintained for coherency. Therefore, properly initiated and executing code accessing the managed portion will be able to read and/or write the managed portion without limitations enforced for coherency. Fibre memory 490-492 is an example of such memory type. A global scheduler or work distribution can participate in setting up the managed portions of cluster-local memories. For example, scheduling abstraction 430 or local storage allocation 208 can perform this function. Coarse scheduler 222 can interoperate with local storage allocation 208 to coordinate allocation of caches used by threads and/or fibres, and the portion of such caches that will operate like caches. In some situations, the cache portion can be treated as a read only memory by fibres so that write back transactions are not generated in furtherance of coherency.
For example, in some implementations, all fibres that reference a particular element of fibre storage can be made to execute on the core with the local storage that has access to that element of fibre storage (in an example where there is a disjoint separation of fibre elements among memories). Therefore, in such implementations, when one fibre that references such memory element instantiates another fibre, some portion of information about the newly instantiated fibre can be kept locally. For example, information identifying the program that the fibre will execute can be kept locally; the location of the fibre memory element being referenced also can be kept locally (in contrast, for example, from sending all fibre data to a central collection maintenance function—here collection forming module 515).
Fibre storage maintenance module 516 in conjunction with fibre memory set up 525 operate to provide or allocate fibre memory storage locations in the distributed memories of cores 543-545. As such fibre storage maintenance module 516 can maintain information about current memory usage in cores 543-545. Such memory usage can include thread local storage for threads in addition to fibre memory storage.
Collection storage 518 stores identifications of fibres correlated with their scheduling key, such that groupings of fibres that have a common scheduling key can be selected and output together. Scheduler 533 can select which grouping of fibres is to be outputted, and by particular example a dispatched packet of fibres 519 is shown. Packet 519 also includes a packet identifier and a packet priority indicator. These elements can be created by scheduler 533 upon selection of a group of fibres based on matching their scheduling keys. Subsequently the fibres of a given packet are distributed among input buffers 540-542 each corresponding to a respective core 543-545. The distribution of the fibres is determined based on where a fibre data elements used by a particular fibre is located among the distributed memories of the cores. Such memory can be selected based on a fibre ID or based on an explicit memory reference, for example.
Each core as it is executing workloads, which can include threads and fibre routines, can output fibre status information 549. Such status information can include, for example, new fibres instantiated by other fibres or threads, as well as information about which fibres have been completed. Information about completing fibres can be used to decrement reference counts of fibres that require access to the same element of fibre storage; likewise, instantiation of new fibres that reference a given element of fibre storage result in increases of such reference counts. These reference counts can be maintained by a given core where a group of related fibres executes or by a centralized resource, as shown in
In one example implementation, collection forming 515 is implemented using a hardware based hash, in which each fibre can be slotted into a collection according to a hash of a respective fibre identifier. The collection forming function 515 groups fibres according to scheduling keys.
In sum,
Such status information is more relevant for implementations where ALU cluster scheduler can interrupt fibre routines during execution, such as on an instruction by instruction basis. However in other implementations, a group of fibre routines from input buffer 267 that have not yet begun execution can be scheduled and can be entirely executed without interruption and execution of a different program stream. In either case, threads can be treated differently, in that ALU cluster controller can interrupt execution of threads, such as for the purpose of executing selected fibre routines from input buffer 267. For example, threads that are executing can be interrupted to perform a fibre routine.
In one example, each fibre can reference different data elements in simple cache 260 and in other implementations multiple of the fibres scheduled for execution on ALU 234-237 can reference the same element of data from simple cache 260. Thus each ALU 234-237 executes the same thread of control, but can operate on different elements of fibre data in different elements of data from simple cache 260. Each ALU further can output information to be stored in thread local and fibre storage 240. These writes are to respective elements of fibre storage and because no two fibres that reference the same element of fibre storage are scheduled for parallel execution by ALUs 235-237, protection mechanisms for thread local and fibre storage 240 for such fibre storage locations is unnecessary in such implementation. Information concerning fibre scheduling and status 564 also can be provided from ALUs 234-237 to ALU cluster controller 230. In turn, ALU cluster controller 230 can update fibre memory location counts 565 to account for new fibres created by fibre routines that have executed and also to account for fibres that now have completed. It is noted however that, in many implementations, ALU cluster controller does not control population of its input buffer 267 with new fibres that have been created. Rather, input buffer 267 is populated by a central controller which also populates one or more other input buffers for other ALU clusters (not depicted here).
As would be understood from the foregoing, memory 589 can be allocated to multiple different management schemes. One portion of memory 589 can be managed as a cache, in which cache management policies such as least recently used can control what data is stored in the memory. Also, such cache portion of memory 589 would have an intention of being coherent with other memory components in a memory hierarchy (e.g., main memory 587). Such cache portion can be arranged as an interleaved memory or other appropriate organizational approach within that cache portion.
In addition to cache portion 594, memory 589 also includes a managed portion, of which fibre storage 591 is an example. The managed portion has characteristics that differ from the characteristics of cache portion 594. The managed portion does not have an expectation or intention of being coherent with other memories in a memory hierarchy (e.g., memory 587). Note that eventually data in the managed portion may be written out to memory 587, or otherwise available for access by non-local computation. However, that writing or accessibility occurs after a sequence of local computation that may include many reads and writes to the memory, for which no memory coherency operations are generated.
Fibres can be scheduled to begin execution based on determining existence of a memory conflict with another executing or scheduled fibre, or instructions from fibres can similarly be dispatched or held for dispatch based on such memory conflict checks. In thread-oriented computing, instructions from a thread are dispatched for execution and memory correctness is maintained by locking memory locations when an instruction initiates a memory transaction that would present a hazard to a different instruction. The different instruction can begin execution, but the thread of which that instruction is a part will halt waiting on the hazard to clear.
As explained above, fibres can be instantiated individually either by a thread or another fibre. However, fibres are dispatched for execution in groups. If a prioritization scheme is desired to be implemented for such groupings of fibres, then one approach to such prioritization is exemplified in
A variety of approaches can be provided to determining a priority for a grouping of fibres based on priorities of individual fibres comprised within that grouping. In one example average of the individual fibre priorities can be used to establish a group priority. In another example of weighted average can be used where a fibre with especially high priority can have a much higher effect on the overall priority of the group then a simple average would have provided. In other implementations, priorities assigned to groupings of fibres can be influenced by the current state of threads executing within the system as well.
In furtherance of such example variations,
It is expected that fibres effect or outputs by writing back to local fibre storage, and do not arbitrate for shared memory resources. Further, in many implementations fibre routines are coded to avoid calling another routine that returns a value and which would cause the fibre routine to stall for an indefinite period waiting for such value to return. Thus for grammatical components and instantiate or otherwise call fibres, in these implementations, also do not need to stall or wait for the fibre to return any value to the calling thread or other fibre. As such, the time to complete execution of any particular fibre is not as critical because other computational flows do not need to be stalled awaiting completion of that fibre.
Scheduling keys were described in many foregoing example implementations. In some implementations, and in some cases, depending on a nature of a workload being performed, scheduling keys can be compressed, or otherwise referenced by shorthand notation. An example workload of ray tracing will be used as an example. In such example, a parent ray tracing thread may output a different fibre for each ray that it wants traced in a scene. Thus, some threads may output a few fibres, some may output tens or hundreds of millions, or billions of fibres. In some cases, each fibre may initially start with the same scheduling key. In an example, such scheduling key can reference a starting storage address of a first element of an acceleration structure that sub-divides the 3-D scene. Elements of the structure can be stored in memory at regular intervals (e.g., each element can be stored in a quadword). As such, a certain kind of fibre routine can be setup to have a default scheduling key; for example, an acceleration structure traversal fibre routine can have the head element of the acceleration structure as a default. Thus, a thread instantiating such fibres does not need to explicitly identify that location.
Examples of acceleration structures include bounding volume hierarchies, such as sphere and rectangle hierarchies and kD-trees, without limitation. For example, in a uniform sphere hierarchy, the elements of such structure are spheres. If the acceleration structure is homogeneous, then leaf nodes in the structure bound primitives; a heterogeneous structure can have elements that bound other acceleration structure elements and primitives.
A variety of structures, devices, components and other constituent elements were depicted and described above, along with interrelationships allowing the flow of data and other information between and among them, and functions and purposes for them were described. These are means for performing the functions and purposes attributed to them in the disclosure.
Code for any method can be stored in non-transitory computer readable media, such as solid-state drives, hard drives, CD-ROMs and other optical storage means, and transiently in nonvolatile memories. A computer readable medium also can include communication signals. When such code is embodied in a communication signal and that signal is read and processed by a computer, the computer uses that signal and its physical medium as a computer readable medium.
Computer-executable instructions comprise, for example, instructions and data which cause or otherwise configure a general purpose computer, special purpose computer, or special purpose processing device to perform a certain function or group of functions. The computer executable instructions may be, for example, binaries, intermediate format instructions such as assembly language, or source code. Some aspects of the API described herein can be implemented as procedures, functions, or calls to such procedures and functions. This description implies no limitation as to a programming methodology that can be used to implement or provide the functionality described as being available through these procedures or functions, so long as software, hardware or a mixture thereof provides a programmer with an ability to access such functionality through an interface provided therefore. These names imply no requirement as to what code performing these functions need to called in an implementation.
In some examples, the computation resources used to execute threads and fibres can be largely undifferentiated. Rather, many of the fibre computing characteristics described herein can be implemented by a central controller that groups fibres for dispatch and dispersion among the computation resources input queues serving these computation resources, and the coordination and counting of which fibres still exist that require a given element of fibre storage.
As would be discerned from these disclosures, one example situation in which fibre computing can be used is a situation where a large number of data elements of a first type, which are not all known a priori, need to be processed or used in conjunction with a large and predetermined data set. In some example situations, the processing of some first type data elements with one portion of the predetermined data set affects how those first type data element are processed with other portions of the predetermined data set. The predetermined data set can vary as well, such as being updated relatively infrequently. In an example graphics application, the predetermined data set may be updated a few hundred times a second and could include many millions of items, which can be accessed millions or billions a second. In general, a centralized scheduler for fibre computing can schedule collections of fibres based on expected maximization of computing throughput rather than explicitly serving the prioritization of any particular fibre.
The various examples described above are provided by way of illustration only and should not be construed as limiting. For example, only a limited example of ray tracing behavior was presented, and it would be understood that practical implementations involve many more rays, and often more concurrent processing thereof. The disclosures herein can be adapted and understood from that perspective. In addition, separate boxes or illustrated separation of functional elements of illustrated systems implies no required physical separation of such functions, as communications between such elements can occur by way of messaging, function calls, shared memory space, and so on, without any such physical separation. More generally, a person of ordinary skill would be able to adapt the disclosures relating to the programming semantic to a variety of other ray tracing/ray shading implementations, and no implied limitation as to its application exists from the systems, methods, and other disclosure used to explain examples thereof
APPENDIX
/* Definitions
/* Input Ray
TypeDef struct _GPUlnputRay {
Float4 a, b;
} GPUlnputRay;
/* An output result
TypeDef struct _GPUResult {
Int4 a;
Floats alpha, beta, float t;
Int flags;
} GPUResult;
/* Internal ray; for GPU traversal
TypeDef struct _GPUlnternalRay {
Floats3 origin, direction;
Unsigned int flags, tid;
Floats alpha, float beta;
Float t;
} GPUlnternalRay;
Inline Bool SphereTest(_fibrestorage GPUlnternalRay *ray),
_read._only _global float4 *sphere_geometry)
{
Bool hit;
/* Perform an intersection test between between ray and *sphere_geometry
if (hit) return true else return false;
}
Inline void TrianglePairTest(_fibrestorage GPUlnternalRay *ray
_read_only _global float4 *scenedata
unsigned int address_qw
{
Bool hit;
Float alpha, beta;
Test triangle(s) at scenedata for intersection
If (hit) {assign elements of ray output to t, tid, alpha, beta}
}
/* Define a fibre routine to test primitives (e.g, triangles) for intersection
_fibre void ProcesriangleChildlist(_fibrestorage GPUlnternalRay *ray,
_read_only _global float4 *scene_data, _fibrekey unsigned int sid)
{
unsigned int address_qw;
compute memory location for scene data → store in address_qw
TriangleTest(ray, scene_data, address_qw);
}
/* Define a fibre routine to test geometry acceleration elements (e.g, spheres) for intersection
_fibre void ProcessSphereChildlist(_fibrestorage _GPUInternalRay *ray;
Read_only _global float4 *scend_data
_fibrekey unsigned int SID; GPUlnternalRay
*ray)
{
float4 sphere_geo;
uint4 sphere_info;
unsigned int address_qw;
}
/* Walk sphere childlist, testing spheres against this ray until completed
do {
Compute address for sphere data;
Load sphere data from global memory
/* Perform sphere test & fork fibre responsive to a hit
if (SphereTest(ray, &sphere_geo){
if(SPHERE_HAS_TRIANGLE_CHILDREN(sphere_info) {
+ProcessTriangleChildList(ray, scene_data, GetChildSID(sphere_info);
else {
+ProcessSphereChildList(ray, scene_data, GetChildSID(sphere_info);
}
} Repeat until sphere list is exhausted
/* Top level thread to control traversal, can declare variables to be assigned fibre storage and
invoke fibres that can access such variables
_Kernel void Traverse (_readonly _global float4 *scene_data
_readonly _global GPUinputray *inputray_data
_writeonly _global GPUresult *result_data)
{
/* Declare element of fibre storage, shared among child fibres
_fibrestorage GPUInternalRay ray;
{
Initialize
/* traverse
if (ray.t > 0.0f) +ProcessShereChildllist(&ray, scene_data, 0) /* Invoke fibre;
ray data in fibre storage
else write out results to result_data[gid] /* alpha, beta, t, flags, etc.
}
}
McCombe, James A., Clohset, Steven J., Peterson, Luke T., Redgrave, Jason R.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
5913059, | Aug 30 1996 | NEC Corporation | Multi-processor system for inheriting contents of register from parent thread to child thread |
6532520, | Sep 10 1999 | Intel Corporation | Method and apparatus for allocating data and instructions within a shared cache |
6820261, | Jul 14 1999 | Sun Microsystems, Inc. | Inheritable thread-local storage |
7015913, | Jun 27 2003 | Nvidia Corporation | Method and apparatus for multithreaded processing of data in a programmable graphics processor |
7103720, | Oct 29 2003 | Nvidia Corporation | Shader cache using a coherency protocol |
7447873, | Nov 29 2005 | Nvidia Corporation | Multithreaded SIMD parallel processor with loading of groups of threads |
7594095, | Nov 29 2005 | Nvidia Corporation | Multithreaded SIMD parallel processor with launching of groups of threads |
7602395, | Apr 22 2005 | Nvidia Corporation | Programming multiple chips from a command buffer for stereo image generation |
7925860, | May 11 2006 | Nvidia Corporation | Maximized memory throughput using cooperative thread arrays |
8200594, | Sep 10 2008 | Nvidia Corporation | System, method, and computer program product for accelerating a game artificial intelligence process |
8345053, | Sep 21 2006 | Qualcomm Incorporated | Graphics processors with parallel scheduling and execution of threads |
8390631, | Jun 11 2008 | Microsoft Technology Licensing, LLC | Synchronizing queued data access between multiple GPU rendering contexts |
8627331, | Apr 30 2010 | NetApp, Inc | Multi-level parallelism of process execution in a mutual exclusion domain of a processing system |
20040263519, | |||
20050120194, | |||
20050240930, | |||
20060143608, | |||
20060230207, | |||
20070030278, | |||
20070273698, | |||
20080005547, | |||
20080074433, | |||
20080077926, | |||
20080143730, | |||
20090083493, | |||
20090322752, | |||
20110050713, | |||
20110057935, | |||
20110131377, | |||
20110141122, | |||
20120151145, |
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